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Structure of Lipids03:38

Structure of Lipids

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Lipids include a diverse group of compounds that are largely nonpolar in nature. This is because they are hydrocarbons that include mostly nonpolar carbon-carbon or carbon-hydrogen bonds. Non-polar molecules are hydrophobic (“water fearing”), or insoluble in water. Lipids perform many different functions in a cell. Cells store energy for long-term use in the form of fats. Lipids also provide insulation from the environment for plants and animals. For example, they help keep aquatic...
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Structure of Lipids03:38

Structure of Lipids

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13.8K
Asymmetric Lipid Bilayer01:35

Asymmetric Lipid Bilayer

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Biological membranes show uneven distribution of different types of lipids in the inner and outer layers, resulting in transverse asymmetric membranes. The treatment of the erythrocyte membrane with the enzyme phospholipase confirmed the asymmetric nature of the lipid bilayer. The enzyme hydrolyzes lipids into fatty acids and hydrophilic groups. The phospholipase acts only on the outer layer of the membrane, while the inner layer remains intact. The phospholipase treatment resulted in 80%...
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Membrane Lipids01:32

Membrane Lipids

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Lipids are an essential component of all biological membranes. The average lipid content in mammalian membranes is 50%, though it can be as low as 20% in the inner mitochondrial membrane or as high as 80% in the myelin sheath present around the nerve cells.
Phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine, and sphingomyelin are the most common phospholipids present in mammalian membranes. At physiological pH, phosphatidylserine is negatively charged, while the other three...
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Structural Protein Function01:56

Structural Protein Function

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Structural proteins are a category of proteins responsible for functions ranging from cell shape and movement to providing support to major structures such as bones, cartilage, hair, and muscles. This group includes proteins such as collagen, actin, myosin, and keratin.
Collagen, the most abundant protein in mammals, is found throughout the body. In connective tissue, such as skin, ligaments, and tendons, it provides tensile strength and elasticity.  In bones and teeth, it mineralizes to...
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What are Lipids?01:38

What are Lipids?

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Updated: Jan 21, 2026

Crystallizing Membrane Proteins for Structure Determination using Lipidic Mesophases
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Crystallizing Membrane Proteins for Structure Determination using Lipidic Mesophases

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Membrane Structure-Function Insights from Asymmetric Lipid Vesicles.

Erwin London1

  • 1Department of Biochemistry and Cell Biology and Department of Chemistry Stony Brook University , Stony Brook , New York 11794 , United States.

Accounts of Chemical Research
|August 7, 2019
PubMed
Summary
This summary is machine-generated.

Researchers developed a cyclodextrin-catalyzed method to create asymmetric lipid vesicles, crucial for studying biomembrane properties and lipid domain formation in both artificial and living cells.

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Area of Science:

  • Biochemistry and Biophysics
  • Membrane Biology
  • Lipidomics

Background:

  • Biomembranes feature asymmetric lipid bilayers, differing from simpler, symmetric artificial models.
  • Understanding lipid asymmetry is key to deciphering membrane functions, including lipid domain organization.
  • Previous methods for creating asymmetric vesicles were limited in scope and versatility.

Purpose of the Study:

  • To develop a novel method for preparing asymmetric lipid vesicles with controlled lipid compositions.
  • To investigate the influence of lipid asymmetry on membrane physical properties, such as lipid domain formation.
  • To extend the lipid exchange methodology to living mammalian cells for in vivo studies.

Main Methods:

  • Utilized cyclodextrin-catalyzed phospholipid exchange between donor and acceptor vesicles.
  • Employed excess donor vesicles and cyclodextrin to facilitate lipid shuttling and leaflet replacement.
  • Extended the method to living mammalian cells, replacing outer plasma membrane lipids without cell damage.

Main Results:

  • Successfully prepared asymmetric lipid vesicles with tunable sizes and lipid compositions.
  • Demonstrated that lipid asymmetry influences coupled physical properties and domain formation in each leaflet.
  • Achieved efficient exogenous lipid replacement in the outer leaflet of living mammalian cells.

Conclusions:

  • The cyclodextrin-catalyzed method provides a versatile tool for creating asymmetric lipid vesicles.
  • Lipid asymmetry plays a crucial role in coupled domain formation within biomembranes.
  • The extended method enables in vivo studies on the functional impact of lipid asymmetry in living cells.